Chemistry of singlet oxygen. XXIV. Low temperature photooxygenation

908 J . Org. Chem., Vol. 41, No. 6, 1976

Burns and Foote

Chemistry of Singlet Oxygen. XXIV. Low Temperature Photooxygenation of 1,2-Dihydronaphthalenesl Paul A. Burns and Christopher S. Foote* Contribution No. 3502 from the Department of Chemistry, University of California,Los Angeles, California 90024 Received November 17,1975

1,2-Dihydronaphthalenesreact with singlet oxygen at -78 O C in acetone to yield products derived from both ene reaction and 1,4 cycloaddition; substitution of a phenyl group on the double bond strongly influences the course of the photooxygenation. The presumed initial 1,4 cycloadducts rearrange and react further to form two isomeric endoperoxide-bisepoxide compounds (2 and 3). The structures of these isomers have been determined; their formation suggests a benzene oxide-oxepin equilibrium at an intermediate stage of the photooxygenation. The dioxygenated products react smoothly with trimethyl phosphite to form triepoxides and with triethylamine to form y -hydroxy-a$-unsaturatedketones, and thermolyze to form dihydronaphthalene tetraepoxides. In the accompanying paper,la it was shown that substituted indenes can be photooxygenated at -78 "C in acetone to give dioxygenated products in good yields. This reaction proved to be so novel and preparatively interesting that its extension to other areas appeared worthwhile, and, for this purpose, a series of dihydronaphthalenes seemed to offer interesting possibilities. Previously, only 1,2-dihydronaphthalene itself had been photooxygenated; at room temperature, the expected ene product was reported.2 1,2-dihydronaphthalene also gives Diels-Alder adducts with both dicyanoacetylene and dimethyl acetylenedicarboxylate, but these reactions require elevated temperatures, and the adducts lose ethylene to form the corresponding substituted naphthalenes under these condition^.^ The results reported in this paper show a varied and interesting chemistry of photooxygenation which depends markedly on the substitution of the dihydronaphthalene.

m-d

'02-78°C , Me,CO

la, R, = H; R, = C,H, b, R,= C,H,; R, = H c, R, = R, = C,H, d, R, = CH,; R, = C6H5 e, R, = CH,; R, = H f , R, = R, = H

23

OOH

Oz,rwmtemp hv e n s

Results Low Temperature Photooxygenation. An acetone solution of l-phenyl- 3,4-dihydronaphthalene ( l b ) was photooxygenated a t -78 O C using rose bengal as sensitizer. As with the indenes,la the solution took up 2.0 equiv of oxygen, and an NMR spectrum showed only dioxygenated products. However, two sets of olefinic protons appeared, indicating the formation of isomeric compounds (2b and 3b) with very similar structures whose spectra were closely analogous to those of diepoxy endoperoxides formed in the indene series.la Under the same conditions, however, 2-phenyl-3,4-dihydronaphthalene (la) reacted with only 1 equiv of singlet oxygen, and NMR showed the ene product (4a) to be the only product. Other dihydronaphthalenes (IC-f) gave mixtures of products 2 and 3 with 4 andlor 5; Table I shows the product composition determined by NMR for all the compounds photooxygenated, along with yields of each compound as isolated. Isolation of the Products. When the reaction solutions were evaporated and redissolved in ether-petroleum ether, one of the two dioxygenated products crystallized preferenti all^.^ This product is designated isomer 2. The other isomer, 3, would not crystallize in the presence of significant amounts of compound 4, the ene product, unless the solution was seeded with crystals previously isolated by column chromatography. This was not possible for compounds 3e,f,

5

as both products had R f values close to those of the ene products. In addition, the dioxygenated compounds slowly decompose on chromatography, further limiting their purity. The products derived from ene reaction, 4, could not be isolated pure enough for analysis. As might be expected, they tend to lose hydrogen peroxide readily; indeed, fractions of this product isolated by chromatography on silica gel were almost invariably contaminated by the corresponding naphthalene. Thus, identification of these compounds was based on their NMR and ir spectra and on their conversion to the naphthalenes. Authentic samples of naphthalenes 6a: 6c,6y7 and 6d7 were prepared by the procedure of Campbell and Kidd5 by

4

6

refluxing a xylene solution containing chloranil and the corresponding 3,4-dihydronaphthalene. These compounds, and purchased samples of 6e and 6f, had NMR and ir spectra identical with those of naphthalenes from compounds 4. Treating 4a and 4e with excess NaBH4 led to the isolation of small amounts of the corresponding alcohols; how-

J.Org. Chem., Vol. 41, No. 6, 1976 909

Photooxygenation of 1,2-Dihydronaphthalenes

1,2-Dihydronaphthalene Tetraepoxides. As did the dioxygenated indenes,’ the dioxygenated dihydronaphthalenes undergo thermal rearrangement. Refluxing benzene or xylene solutions of 2 or 3 gave tetraepoxides 7 or 8 in -75% yield. In the two cases where the endoperoxides were not

Table I. Products of Photooxygenation of 1,2-Dihydronaphthalene# Products of “Ene” reaction

[ 2 + 41 attack

Compd R, la

H

l b C,H, IC C,H,

R2 C,H, H C,H,

2%

2, %

3, %

0 40(33) 25 ( 2 0 ) 4d 25 ( 1 3 ) 37.5 (17)

4,

0 60(34) 40 ( 3 2 ) 6d 35 37.5

%b

100 0 35 85 40 25

5, % c c c

5 CH, e CH, H c If H a Determined by NMR; numbers in parentheses are isolated yields. b Not isolated in pure form because of ready loss of H,O,. c Not applicable. d Compounds 2d and 3d were not isolated; the assignment is based on analogies to the chemical shifts of the products of the other reactions. ePresence uncertain; if present, the yield is included in the yield of compound 4e.

Id le

7,8

23

nD

9,lO

ever, on drying under high vacuum, the alcohols lost water to form the naphthalenes. Characterization of the Dioxygenated Products. The analyses and mass spectra of the photooxygenation products were consistent with starting material plus two molecules of oxygen, although, unlike the analogous indene products,la the peaks for P - 32 (loss of oxygen) were not significant. The ir spectra showed neither carbonyl nor hydroxyl absorptions, but there were many strong bands between 750 and 1280 cm-l, the region containing substituted epoxide ring vibrations.8 The compounds give a positive test for peroxide with acidified starch-iodide paper. The NMR spectra of these compounds are tabulated in Table

isolated (3e and 3f), the photooxygenated solutions, after crystallization of the other isomers (2e and 2f), were evaporated and heated under vacuum at -90 “C for several hours. In this manner, the ene products were converted to their corresponding naphthalenes, which did not interfere with the isolation of the tetraepoxides. The isomeric tetraepoxides (7 and Ob,c,e,f) were isolated and purified in 2658% yield by repeated crystallization from benzene-heptane solution. The minor products of the thermolysis are &epoxy ketones (9 or 10); an ir spectrum taken after each reaction showed a carbonyl band a t -1725 cm-l and no hydroxyl band. These ketones are very sensitive to base, and readily isomerize to the corresponding y-hydroxy-a,@-unsaturated ketones (11 or 12). However, it was possible to isolate and characterize 9e. The NMR spectra of the tetraepoxides are summarized in Tables I11 and IV. In contrast to the indene tetraepoxides,la the relative chemical shifts o protons A-D show no general trends. In fact 8b, 7e, and 7f have almost equivalent chemical shifts for protons B-D. The assignment as A-D (and not the reverse, with A = D, etc.) was based on the following arguments. (1) As in the indenes, there is an upfield shift of 6 0.6-0.8 for proton A owing to the shielding of phenyl substituents; proton D shows only a small upfield shift. (2) This assignment gives the protons with the Oo dihedral angle the larger coupling constants (see Discussion). (3) This assignment then agrees with that of the indene tetraepoxides,la which was confirmed by 13C NMR;1° the

.II. The NMR spectra all show two olefinic protons, an endoperoxy CH proton, and an epoxide proton that form an ABXY system (protons A-D). There are also one or two additional epoxide protons, depending on the substitution at positions E and F, and two methylene groups. The spectra are exactly analogous to the spectra of the dioxygenated indenes;la the only difference is that, with the exception of 2b, the ABXY system is degenerate (or simplified) because the difference in the chemical shift of the olefinic protons, A and B, is small ( Jtrans observation of Toriz9that in 1,2-epoxycyclopropanethe couplings between the epoxide and methylene protons are smaller than predicted for dihedral angles between 0 and 50'.

916

J.Org. Chem., Vol. 41, No. 6,1976

Fields and Meyerson

(28) M. Karpius, J. Am. Chem. SOC.,85, 2870 (1963). (29) K. Tori, T. Komeno, and T. Nakagawa, J. Org. Chem., 29, 1136 (1964). (30) The analogous indene compounds also have this geornetry.la (31) J. P. Quiliet, A. Duperrier, and J. Dreux, Bull. SOC. Chim. Fr., 255 (1967). (32) J. Jacques and H. B. Kagan, Bull. SOC.Chim. Fr., 128 (1956).

"Handbook of Chemistry and Physics", R. C. Weast, Ed., 4th ed, Chemicai Rubber Publishing Co., Cleveland, Ohio, 1964. (34) R. L. Shriner, R. C. Fuson, and D. Y. Curtin, "The Systematic identification of Organic Compounds", Wiiey. New York, N.Y., 1960, p 241. (35) The lower fieid of protons A and D was assigned as A based on the analogous indene triepoxides." (33)

Thermal and Photochemical Decomposition of Silver Carboxylates Ellis K. Fields* Amoco Chemicals Corporation, Naperville, Illinois 60540

Seymour Meyerson Standard Oil Company (Indiana), Naperville, Illinois 60540 Received September 19,1975 Silver salts of carboxylic acids decompose a t 200-350 "C to silver, carbon dioxide, and radicals. Silver benzoate a t 276 "C gives polyphenyls containing two to five benzene rings, as well as benzene, benzoic acid, and 3,4-benzocoumarin. Arylation of benzophenone was effected by silver benzoate a t 300 O C , along with formation of biphenyl and benzophenone dimer. An intimate mixture of silver isonicotinate and silver benzoate a t 275 "C gave coupling products of phenyl and pyridyl radicals with themselves and with each other. Silver trifluoroacetate decomposes thermally above 260 "C or irradiated with ultraviolet light in solution at 25 "C, to silver, carbon dioxide, and trifluoromethyl radicals. As silver trifluoroacetate, unlike most silver salts, is relatively soluble in organic solvents, it may be used as a convenient source of trifluoromethyl radicals. With benzene a t 325 "C it gave 38 mol % of benzotrifluoride; 57 mol % of benzotrifluoride resulted from the photochemical reaction. Benzonitrile gave a good yield of the three isomeric trifluoromethyl benzonitriles, mainly ortho. With 4-benzoylpyridine a t 300 "C silver trifluoroacetate gave derivatives formed predominantly by addition of trifluoromethyl radicals to the benzene ring. Silver salts of polycarboxylic acids decompose a t 200-425 "C to silver, carbon dioxide, and products apparently formed from polyradicals. Silver isophthalate, pyrolyzed under nitrogen a t 375 "C and cooled under hydrogen, gives silver imbedded in a black, carbonlike polymer that ignites a t 25 "C when exposed to air. Different silver salts give a wide variety of different shapes upon being pyrolyzed. Heteroatoms are retained; silver pyridine-3,5dicarboxylate a t 310 O C yielded carbon dioxide, silver, and black polymer with the theoretical amount of nitrogen. Considerable control of pore-size distribution and surface area for silver imbedded in carbonlike polymers has been achieved by pyrolyzing the appropriate silver polycarboxylate. Silver carboxylates represent a new class of stable radical precursors of great variety, ready availability, and easy preparation.

As organic chemistry developed in the middle and late 19th century, silver salts of carboxylic acids were among the first derivatives prepared, primarily because they were easy to make and to purify. Surprisingly, except for a few scattered references in the literature dealing with explosives,l the behavior of silver carboxylates a t elevated temperatures has been wholly ignored. We have discovered that silver carboxylates decompose, when heated, according to the scheme 0

may result from dimerization of phenyl radicals trapped in a solid matrix, although dimerization is not favored in liquid or gas phase reactions of phenyl radicals? C,H,CO,Ag

- -

-Ag

C,&CO,

-

co

C ,H,C02.A C,H, CbHj '

+ C,H,CO,Ag

[HI

'

. CHI

C6HjCO2H CJ3,

-[HI -----t

0

As an example, 45.8 g (200 mmol) of silver benzoate (276 "C dec), heated in a Pyrex tube under a stream of nitrogen to 280 "C for 1 min, gave the products shown in Table I. The gas evolved, together with benzoic acid and benzocoumarin, accounted for 196 mmol (98%) of COz; the products listed in Table I accounted for 197.4 mmol (98.7%) of phenyl radicals. Silver benzoate was pyrolyzed under a variety of conditions: diluted with twice its weight of silica; in a bomb under 300 psi autogenous pressure; and in a pellet formed under 10 000 psi. In all cases the identical products were formed and in about the same proportions. Benzene and benzoic acid are the products of hydrogen abstraction by phenyl and benzoyloxy radicals, respectivel ~Biphenyl . ~ and higher polyphenyls may form by phenylation of silver benzoate and subsequent decomposition; ortho phenylation gives 3,4-benzocoumarin. Some biphenyl

C6H6.iC,HjCO,Ag

-

-[HI

n

Silver salts of substituted benzoic acids behave similarly to silver benzoate. Silver p -fluorobenzoate and silver pentafluorobenzoate, each decomposed a t 300 "C under nitrogen, gave the products shown in Tables I1 and 111, respectively. Among the heterocyclic compounds, silver thiophene-2carboxylate a t 275 "C gave thiophene and bithiophene in a weight ratio of 3:l. Silver salts of pyridinecarboxylic acids a t 280-320 "C gave bipyridyls and terpyridyls with varying amounts of pyridine, as shown in Table IV. Hydrogen ab-